PRIMARY INJECTION CIRCUIT BREAKER TEST SET · 2020-01-07 · PRIMARY INJECTION CIRCUIT BREAKER TEST...

PRIMARY INJECTION CIRCUIT BREAKER TEST SET

INSTRUCTION MANUAL

Models

PI-2500 and PI-5000

Electrical Test Instruments, LLC. 1301 Avondale Road, Suite J

New Windsor, MD 21776

www.ETIPrecision.com

(410) 857-1880 Fax (410) 857-1387

Electrical Test Instruments PI-2500 and PI-5000 ==============================================================================

============================================================================== Copyright (C) 1994-2008 Electrical Test Instruments, LLC. All Rights Reserved

TABLE OF CONTENTS SECTION I: GENERAL INFORMATION and SPECIFICATIONS WARNING I-1 Introduction I-2 General Description I-2 Monitor and Controller MAC-20 I-5 Proposed Enhancements I-5 Advantages Compared to Other Test Sets I-6 Trademarks I-6 PI2500 Specifications I-7 PI5000 Specifications I-7 MAC-20 Specifications I-8 SECTION II: DETAILED DESCRIPTION Theory of Operation

High Current Test Sets II-1 PI-2500 Main Circuitry II-1 PI-2500 Control Circuitry II-1 AUX-5000 Main Circuitry II-1 AUX-5000 Control Circuitry II-1 PI-2500 Indicator Control Panel Circuitry II-4

MAC-20 Monitor Controller Circuitry II-4 MAC-20 Software II-5 Major Parts Identification and Operation MAC-20 Control Panel II-6 MAC-20 Internal Parts II-9 Figure II-1: Front Panel II-10 Indicator Control Panel II-11 Figure II-2: Retrofit Indicator Panel II-12 SECTION III: MAC-21 Monitor and Controller MAC-21 Specifications III-1 MAC-21 Unit Circuitry III-2 MAC-21 Software III-2 MAC-21 Parts Identification and Operation III-4 MAC-21 Internal Parts III-8 Figure II-1: Front Panel III-9 Maintenance and Calibration of MAC-21 III-10 Parts List (MAC-21) III-12 Overall Schematic (MAC-21) III-13

Electrical Test Instruments PI-2500 and PI-5000 ==============================================================================

============================================================================== Copyright (C) 1994-2008 Electrical Test Instruments, LLC. All Rights Reserved

SECTION IV: OPERATING INSTRUCTIONS Pre-Test Installation and Setup IV-1 Basic Guidelines and Suggestions IV-3 Single Pole Molded Case Breakers IV-4 Multi-pole Molded Case Breakers IV-7 Low Voltage Power Breakers IV-10 Motor Overload Relays IV-14 Ratioing Current Transformers IV-16 SECTION V: SERVICE INFORMATION AND DOCUMENTATION Maintenance and Calibration of PI-4000B V-1 Maintenance and Calibration of MAC-20 V-1 Parts List (PI-2500) V-4 Parts List (AUXI-5000) V-4 Parts List (Indicator Control Panel) V-5 Parts List (MAC-20) V-6 Overall Schematic (PI-2500) V-7 Overall Schematic (AUX-5000) V-7 Overall Schematic (Indicator Control Panel) V-8 Overall Schematic (MAC-20) V-9 Warranty END Additional Schematics END

Electrical Test Instruments PI-2500 and PI-5000 Section II – Detailed Description ==============================================================================

============================================================================== Copyright(C) 1994-2008 Electrical Test Instruments, LLC. All Rights Reserved

SECTION I

GENERAL INFORMATION

Electrical Test Instruments PI-2500 & PI-5000 Section II - Detailed Description ==============================================================================

============================================================================== Copyright(C) 1994-2008 Electrical Test Instruments, LLC. All Rights Reserved Page II-1

SECTION I

GENERAL INFORMATION

WARNING

WARNING - READ THIS ENTIRE MANUAL AND THOROUGHLY FAMILIARIZE YOURSELF WITH THE UNIT OPERATION PRIOR TO CONNECTING THE UNIT TO A SOURCE OF POWER. HIGH CURRENT TEST SETS ARE NORMALLY POWERED FROM HIGH CAPACITY 208 VOLT TO 575 VOLT SERVICES, AND IMPROPER CONNECTION OR OPERATION COULD CAUSE DAMAGE TO THE TEST SET AND EQUIPMENT UNDER TEST, AS WELL AS CREATE AN UNSAFE CONDITION FOR PERSONS OPERATING THE SET.



INTRODUCTION

A primary injection test set such as the PI-2500 and PI-5000 is a device with high current, low voltage AC outputs for testing direct acting low voltage circuit breakers. Current is injected through the main contacts of the breaker to simu-late actual fault conditions, which tests the operation of CTs, solid state, thermal, or electromechanical trip devices, and the actual trip mechanisms and breaker contacts.

GENERAL DESCRIPTION – PI2500

The PI-2500 is a versatile and technologically advanced primary injection test set capable of testing circuit breakers up to 2000 amperes frame size. It incor-porates an improved low impedance output transformer with dual primaries to facilitate its use on power sources of 480 VAC as well as 240 and 208 VAC, and dual secondaries to provide optimal impedance matching to a wide range of breaker sizes. High capacity internal fan cooling allows maximum utilization of the output transformer and faster recovery after overload conditions.

It is housed in a rugged aluminum frame enclosure with removable sides and top for easy access to internal components. The sides are clear of protruding components, and a full-width handle facilitates moving the unit. Locking pneu-matic swivel castors on one end provide ease of mobility and allow the test set to be moved on rough surfaces.

The indicator control panel and MAC-20 are mounted in a compact hood on the top, which provides protection during transportation. A flat area on the top sur-face can be used for convenient placement of manuals, breaker curve books, and auxiliary instruments. The auxiliary 120 VAC GFI protected outlet is conven-iently located on the rear of the unit and protected by a 4-ampere circuit breaker.

The output stab connectors are slotted to accommodate special breaker stab adaptor plates as well as being able to connect to the AUX-5000 for increased output capacity. The rugged silver-plated copper stab adaptors supplied with the test set are designed to be used for both vertical and horizontal stabs and have both ½” and ¾” output plates. Standard ½”-13 stainless steel hex head bolts with matching nuts and washers are used to connect the output stab plates, and they may be replaced easily.

A series adaptor bar allows the output to be configured for continuous current of 1000 amps at 15 VAC for testing breakers that require connection via cables. A configuration switch on the output faceplate adjusts the internal CT output for proper readings in either configuration.



The test set may be plugged into any 60 Hz AC voltage source of 200-250 VAC or 400-500 VAC, and will work on 50 Hz sources of 200-210 VAC or 400-420 VAC. The line voltage is displayed on the indicator control panel digital meter. An in-put selector switch can be set for 208, 240, or 480 VAC inputs. An internal volt-age sensor automatically ensures that the switch is set correctly before AC con-trol power can be turned on, and monitors input voltage for compliance to spec-ifications.

The Vernier uses a large wheel to adjust the output manually within the range determined by the coarse tap, as well as a motorized control actuated by means of a smart control switch. When the switch is pressed briefly, the Vernier moves in a very small increment for fine control. When the switch is held, the Vernier moves very quickly, so that the entire span may be traversed in less than five seconds. The approximate Vernier position is displayed on an LED indicator bar graph. For the PI-2500, the Vernier is always turned clockwise to increase out-put.

The electronically controlled tap selection uses power contactors to set the coarse tap. The unit powers up in the lowest tap position (1), and the setting may be adjusted by means of a rocker switch on the indicator/control panel. If the switch is held, the taps change at a rate of about two seconds per tap. Tap change is not allowed when output is on. Note: Output taps 1-3 only for the PI-2500. Output taps 4-9 are only operational when the AUX-5000 section is con-nected to the PI-2500 section.

The indicator/control panel features two temperature indicators: one for the output bus temperature, and the other for the overall system temperature. This is determined by a combination of actual winding temperature, and a “virtual temperature” which is derived from time and current duty cycle usage as mon-itored by a “POD”, or Programmable Overload Device. Additional details are available in a separate manual. If either temperature exceeds a safe operating level, the interlock is asserted, and the output section is de-energized. Addi-tional thermostatic sensors in the output transformer windings will also assert the interlock if unsafe temperature levels are detected.

The output voltage of the test set is provided on the indicator/control panel for monitoring by means of a separate digital voltmeter.

Primary catastrophic overload protection for the test set is accomplished with input fuses having high interrupting current capacity. Overload of the output system is sensed by means of the previously mentioned “POD” on the Vernier autotransformer, and thermal sensors in the transformer winding. Thermal switches are also installed in the transformer windings. The combination of these devices allows full utilization of the overload capability of the test set and eliminates costly and cumbersome fuse replacement required in other test sets.



The output of the test set is controlled by means of a proven SCR controller, which drives modular solid-state relays. This provides precise initial phase angle control to reduce DC offset for inductive loads and more consistent pulse cur-rents. Snubbers are incorporated to eliminate false firing and latching problems. The phase angle is internally adjustable and is preset for optimal waveforms with most breakers.

The measurement of output current and time is accomplished by means of the proven MAC-20, which uses highly accurate A/D circuitry and intelligent firm-ware to resolve true-RMS values of distorted waveforms. It also provides features such as preset ON times for convenient jogging of output current without over-heating the breaker or causing unwanted trips.

The entire test set has been designed for reliability, ruggedness, and ease of use. Sophisticated electronics in the indicator/control panel and the MAC-20 provide state of the art accuracy and convenience, while simple connections allow for easy removal and replacement for transportation or service. All covers are re-movable, allowing easy access to all internal components. An internal relay panel located just under the top panel contains most of the circuitry, facilitating service and maintenance. The rear panel may be removed for access to input fuses, control fuses, and the SCR board. A large bottom-mounted fan provides airflow to the transformer and output bus. The cabinet is designed with no pro-truding components on the sides, so it can be navigated through narrow door-ways without problems. The input jacks and voltage switch are protected by being mounted on a recessed rear panel.

The reduced length and width of the test set allows it to be maneuvered in tight spaces and it can be lowered into a shaft 26” x 30”, or a manhole 40” diameter. Provisions have been made on the bottom of the frame for a lifting sling to be attached without slipping from the corners.

GENERAL DESCRIPTION – PI5000

The PI-5000 is composed of the PI2500 as described above, and the AUX-5000 auxiliary output unit, which when combined gives the unit the capability of testing 4000 ampere breakers, with essentially the same specifications as the proven PI-4000B. The auxiliary unit is smaller than the PI2500, so it can also be maneuvered easily in tight spaces or lowered into shafts and manholes that would not be possible with a larger single piece unit.

The AUX-5000 is easily attached to the PI-2500 by means of horizontal bus bars with stainless steel socket head cap bolts and sturdy nutplates. The AUX-5000 is simply rolled into place to mate with the PI-2500, and then the cap screws are tightened. It is recommended to use a stubby fine pitch ratchet wrench or a pneumatic air ratchet, with an Allen wrench hex bit.



The main electrical power and ground connections to the AUX-5000 are the same twist-lock connectors as those on the PI-2500. Power cables stored in a compartment in the AUX-5000 are then connected to the PI-2500. The con-nectors are color-coded and must be connected with black to black and red to red.

There is also a control cable which connects from the AUX-5000 to the PI-2500.

The output of the AUX-5000 is identical to that of the PI-4000B, and accom-modates standard breaker stabs, for continuous output of 4000 amperes. It can also be configured in series mode for a continuous output of 2000 am-peres. The configuration switch on the PI2500 must be set to 4000 or 2000 for proper output readings.

The combined unit, known as the PI-5000, can only be used on 480 VAC.



MONITOR AND CONTROLLER MAC-20

The MAC-20 microprocessor-based measurement and control unit features digital readout of current and time enhanced by digital signal processing. Pulse (memory) mode provides fast and accurate automatic evaluation of out-put current pulses as short as one-half cycle.

The MAC-20 incorporates a precision A/D converter and special firmware for true-RMS continuous and pulse current reading with much greater accuracy. It also utilizes a sophisticated current sensing system for more reliable current latch mode operation and better timing accuracy. An LED digital readout for current in four ranges from 1000 A to 100 KA reduces the chance of operator error.

An integral auto ranging timer with LED readout provides four digits in sec-onds or cycles mode, with a resolution of 0.001 second or 0.5 cycle. A preset function allows you to set a maximum ON time in seconds or cycles, for con-venient "jogging" of output to desired current or setting time for heat runs and long-time tests.

A current hold feature is also built in. When the desired current is displayed, a simple touch of the MAINTAIN key activates the function, which automatically adjusts the motorized Vernier to hold the current within 5 amperes.

The memory current displayed after a test indicates the true RMS value of the entire pulse, no matter how long or short it was, except for instantaneous trip, where the peak RMS value is used. After a test, it is possible to read the peak RMS value, which indicates the amount of DC offset or distortion, or the last displayed average RMS reading, which is useful for pickup testing.

The entire metering and control package are designed to be removed and re-placed very easily, so that it may be transported separately.

A remote-control accessory is available which allows the Vernier to be oper-ated by means of a small hand-held control, which also allows the test set to be initiated.



PI-2500 SPECIFICATIONS INPUT SUPPLY: 208/240 or 480 VAC +/- 10% (Field switchable) SINGLE PHASE 60 HZ (50 Hz at 10% lower line voltages) 15 KVA (Continuous) at 12 KVA output (80% efficiency) OUTPUT CURRENT & OVERLOAD CAPABILITIES:

7.6V (Par) 15.2 V (Ser) Ovld Duty Max ON Time Min OFF Time

Max Inp Curr (@480/240)

2000 A 1000 A 1x 100% CONTINUOUS

N/A 32 / 64

2800 A 1400 A 1.4x 50% 15 Minutes 15 Minutes 45 / 90 4000 A 2000 A 2x 25% 5 Minutes 15 Minutes 64 / 128 6000 A 3000 A 3x 10% 1.5 Minutes 15 Minutes 96 / 192 8000 A 4000 A 4x 6% 45 Seconds 15 Minutes 128 / 256

10000 A 5000 A 5x 4% 4 Seconds 2 Minutes 160 / 320 14000 A* 7000 A* 7x 2% 1 Second 2 Minutes 224 / (448 *) 20000 A* 10000 A* 10x 1% 0.2 Second 2 Minutes 320 / (640 *)

*Available with 480 VAC input only; Max ON Times may be less at 208 or 240 VAC DIMENSIONS AND NET WEIGHT Height: 41 in. (1041 mm) (includes castors and hood) Width: 29.0in. (737 mm) Depth: 25.0 in. (635 mm) Weight: 515 lb. (192 kg) STANDARD ACCESSORIES Stabs, BS-50HV (½” bus, horizontal or vertical) 1 set Stabs, BS-75HV (¾” bus, horizontal or vertical) 1 set Stab adaptor assembly 1 pair Series bars 3 pcs Input power plugs 3 pcs Contacts leads 1 pair Technical manual 1 copy OPTIONAL ACCESSORIES Remote initiate cable Serial Interface Cable



PI-5000 SPECIFICATIONS INPUT SUPPLY: 480 VAC +/- 10% SINGLE PHASE 60 HZ (50 Hz at 10% lower line voltages) 45 KVA (Continuous) at 36 KVA output (80% efficiency) OUTPUT CURRENT & OVERLOAD CAPABILITIES:

7.6V (Par) 15.2 V (Ser) Ovld Duty Max ON Time * Min OFF Time Max Inp Curr (@480 4000 A 2000 A 1x 100% CONTINUOUS N/A 96 5600 A 2800 A 1.4x 50% 15 Minutes 15 Minutes 134 8000 A 4000 A 2x 25% 5 Minutes 15 Minutes 192

12000 A 6000 A 3x 10% 1.5 Minutes 15 Minutes 288 16000 A 8000 A 4x 6% 45 Seconds 15 Minutes 384

20000 A 10000 A 5x 4% 4 Seconds 2 Minutes 480 28000 A 14000 A 7x 2% 1 Second 2 Minutes 672 40000 A 20000 A 10x 1% 0.2 Second 2 Minutes 960

DIMENSIONS AND NET WEIGHT PI-5000 AUX Height: 35 in. (889 mm) (includes castors) Width: 30.0 in. (762 mm) Depth: 25.0 in. (635 mm) Weight: 585 lb. (218kg) DIMENSIONS AND NET WEIGHT PI-5000 (Combined PI-2500 & PI-5000AUX) Height: 41 in. (1041 mm) (includes castors and hood) Width: 48.0 in. (1219 mm) Depth: 25.0 in. (610 mm) Weight: 1100 lb. (411kg) STANDARD ACCESSORIES Stabs, BS-50HV (½” bus, horizontal or vertical) 1 set Stabs, BS-75HV (¾” bus, horizontal or vertical) 1 set Input power plugs 1 pair Contacts leads 1 pair Technical manual 1 copy Remote initiate cable 1 each OPTIONAL ACCESSORIES Series bar Serial Interface Cable



SECTION II DETAILED DESCRIPTION



SECTION II

DETAILED DESCRIPTION THEORY OF OPERATION High Current Test Sets High current test sets generally consist of the following:

1. One or more coarse taps accomplished by: (a) A tapped autotransformer providing several equal steps of volt-

age or (b) A multi-section output transformer

2. A continuously variable Vernier adjustment between coarse taps by means of:

(a) A variable autotransformer and boost transformer, or (b) A variable autotransformer connected to a section of the out-

put transformer. 3. An output transformer with one or more isolated low voltage, high

current secondary. 4. Power control circuitry consisting of switches, relays, protective de-

vices, etc. 5. Current measurement circuitry consisting of sensors, current meter,

and timer. In general, a primary voltage is selected by means of a combination of coarse tap and Vernier adjustment. This voltage is stepped down by the output trans-former to provide the desired current into the load impedance. PI-2500 Main Unit Circuitry Main power is applied to the PI-2500 by means of standard high current plug and socket connectors, which are supplied for the customer to connect to the power source with appropriate flexible leads. A ground connector is also pro-vided for a solid ground connection.

Primary protection is provided by high capacity 100 ampere input fuses (F1 and F2). After that, the control section is protected by smaller 5 ampere fuses (F3 and F4), and the power section is isolated by means of high current contactors (K1 and K2).

Transformer T6, protected by fuse F6, steps down the primary voltage by a factor of ½, and is connected to a wide range switching power supply in the indicator



control panel to provide 12 VDC. The dual primary of transformer T6 steps it down by a factor of 1/2, and T10 steps it down by another factor of ½, and this voltage is sensed by a voltage relay circuit and read on the control panel LED meter. When the primary voltage is between about 200 and 270 VAC, this circuit allows operation in 208 or 240 VAC mode. If the voltage is between about 420 and 520 VAC, operation is allowed in 480 VAC mode. Control power cannot be turned on if the voltage is outside these bounds.

When AC power is supplied to the test set, the 24 VDC power supply PS1 is pow-ered through the stepped down primary winding of T6, and will operate from supply voltages of 500 to 190 VAC. This DC control voltage is used for all of the tap contactors. There is a current limiting circuit which is required to keep the output of the power supply from shutting down while charging the large ca-pacitors that are needed to pull in the contactors.

Another transformer, T9, supplies nominal 104, 120 or 240 VAC power to the con-trol panel, which has an internal 12 VDC power supply which powers other por-tions of the control circuitry of the control PCB.

When the input voltage selector switch S1 is the 208 or 240 V position, relay K6 is energized, setting the primary windings of transformer T4 in parallel. This also energizes relay K1 on the voltage sensor PCB and provides an interlock and in-put selector error indication. The voltage sensor PCB rapidly flashes the Input Select Error LED on the control panel for 5 seconds during startup, and then turns off if input voltage is within bounds as determined by the input selector switch position. If line voltage is incorrect, the Input Select Error LED will flash, and control power cannot be turned on. If control power is energized, brief volt-age sags or surges will flash the LED as a warning. If such voltage excursions persist for longer than about 0.2 seconds, the control power will drop out.

Binding post BP1 is provided for separate connection to an earth ground, to check for ground integrity. When there is continuity from this point to chassis ground, a relay on the control PCB is energized, and enables the interlock for control power. If ground integrity is not sensed, the Ground Open LED DS1 will light. A separate lead should be connected to the external equipment ground system to verify that the main grounding cable is intact. Do not defeat this safety feature by jumpering the ground binding post to the test set frame.

When the control power switch in the indicator control panel is pressed, and all voltage interlocks are OK, relay K7 is energized, which provides 120 VAC control power to the auxiliary GFI outlet, protected by 4 ampere circuit breaker CB1. A relay on the control PCB provides 120 VAC control power to the entire test set, including the fans and the main contactors. In 208 V input mode, the control voltage is boosted by transformer T7.

If all power interlocks are OK, the Main Power switch in the indicator control panel may be pressed to activate main contactors K13-14. This provides high



current power to the test set output circuitry through the SCR controller. The switched output voltage is supplied to distribution blocks DB1 and DB2.

The Vernier autotransformer T1 and output transformer T2 are connected to in-put voltage selector switch S11. This allows for connection in series for 480 VAC, and parallel for 208/240 VAC. Vernier T1 is connected directly to the first primary of T2, so that clockwise rotation produces an output voltage of about 0-1.5 VAC. Relays K3, K4, and K5 connect the second primary windings for fixed outputs of 0, 1.25, or 2.50 VAC for taps 1, 2 and 3. This provides three (3) overlapping output ranges up to 3.75. 7.5 or 15 VAC, depending on how the four secondary windings are connected.

Output current is detected by means of an air core CT around all four main bus-ses. The configuration switch can be set to 1000, 2000, or 4000, which divides the signal by a factor of 4, 2, or 1. Calibration of all three modes is accomplished with potentiometers on the switch assembly under the output face plate.

The output section is energized when a signal is applied to the trigger board of the SCR controller. The initial phase angle is determined by a zero-crossing de-tector in the trigger PCB, and a delay which is normally preset to 70 degrees. There are three solid state relays, one of which powers the Vernier assembly, and the others power the second primary on the output transformer.

The Vernier autotransformer may be adjusted manually by means of a hand-wheel, or by activating the motor drive. Increasing output is clockwise for all taps.

When the SCR board is energized, 12 VDC is applied to the control panel which is used for output ON detection and indication.

Thermistor TH2 senses the temperature of the output bus, and TH1 reads the temperature of the first primary of output transformer T1. These normally have a resistance of 10 K ohms at room temperature, and lower values as the temper-ature increases.

Relays K3 through K5 are energized through the indicator control panel and the control PCB. They may be equipped with electrical interlocks to avoid damage if all three are simultaneously energized. The relays actually have 24 VAC coils which are driven with a pulse of 24 VDC long enough to cause them to seal in, and then are held by a lower current through power resistors on the control PCB. This type of contactor is not available with a DC coil, and DC was chosen to avoid relay chatter that can occur with AC relays if line voltage momentarily drops.

The adjustable Vernier assembly T2 in the PI-2500 consists of a stack of four 120 VAC decks, with each series connected pair connected to a 240 VAC primary on T1A. Minor voltage imbalance up to about 2 VAC is corrected by means of paral-leling transformer T3, and actual current in each primary circuit is monitored by means of 50:5 current transformers T4 and T5. Resistors R1 through R4 ensure



voltage balance on the series connected pairs, and also provide a resistive load to stabilize the SCR controller at low output settings.

The secondary currents from T4 and T5 are monitored by the Programmable Overload Device (POD), which also measures actual temperature in the primary winding of T1A. The overall system status is displayed on the bar graph of the indicator control panel, and an interlock relay shuts down the output of the test set if abnormal conditions are detected. More details are in a separate manual.

The PI-2500 features a very efficient low impedance output transformer with enhanced reliability and cooler operation due to single piece secondary bus conductors. It was designed so that it could provide three connection modes for 1000, 2000, and 4000 amps continuous current. Stab Adaptor Plates and se-ries bars are used for convenient output connection. The output bus connectors are slotted so that the hardware can be loosened and removed or replaced eas-ily. A slotted brace is supplied that helps with alignment. See the following illus-tration for details:



Illustration of PI-2500 Stab Plate Assembly:

AUX5000 Main Unit Circuitry The AUX-5000 auxiliary unit connects to a 480 VAC supply and ground by means of standard input jacks. Primary protection is provided by 200-amp fuses F1 and F2. Main power is supplied to the output section by power contactors K1 and K2, which are energized when those in the PI2500 are turned on. There are three solid state relays, which control power to the three sections of the output transformer T1. They may be protected by fuses, and they are equipped with snubbers to prevent spurious turn-on and latching of output.

Contactors K3 through K8 are operated for taps 4 through 9, and their coils are driven by 24 VDC pulses from the Auxiliary Relay PCB. The primary of each trans-former section is shorted when it is not needed; otherwise it is powered through the SSR. Electrical interlocks on the contactors assure that both cannot be pulled in at the same time.

The control connector to the PI2500 provide ACHI and ACLO power for the fan, control signals for the contactors, initiate signal for the solid-state relays, inter-locks, and sense leads for the output bus voltage from terminal 1 to 4.

The secondary windings of the transformer, consisting of two pairs of bus bars, are bolted to the secondary bus bars of the mating PI-2500. The combined units form a transformer which is nearly identical to the PI4000B.

The high strength and corrosion resistant stainless-steel output bolts should rarely require replacement but may be serviced by simply removing the sixteen screws on the phenolic output faceplate, and then removing one of four bolt retainers. The standard hex head bolts may then be pushed through and re-placed.



PI-2500 Indicator Control Panel Circuitry

The power for the control panel is provided by the INV/2 circuit, which is the main input voltage divided by 2. This voltage, ranging from 104 VAC to 240 VAC, powers a wide range switching power supply, which supplies 12 VDC to the rest of the circuitry. When the CTL ON switch S1 is pressed, DS1 lights and relay K4 is energized, and latches on if voltage interlocks are OK and the external control relay energizes. K4 also provides 12 VDC power to the PC board, which has cir-cuitry for Vernier position display and adjustment, tap selection and display, and temperature readings. Pressing S2 turns control power off.

If any external interlock is open, as sensed by K1, indicator DS4 will light. Other-wise, K2 will energize, which energizes K2 and allow operation of S3. When MAIN ON switch S3 is pressed, relay K3 energizes, MAIN READY lamp DS3 lights, and power is provided to external main contactor. If it operates, K3 is latched on through its auxiliary contact.

If the output of the test set is ON, 12 VDC will be applied to DS5, and also will be sensed by the PC board, which will inhibit tap change.

The INV/4A and B signals provide a voltage equal to ¼ the input voltage. This is rectified and filtered by the metering PC board and displayed on the panel me-ter.

Output is inhibited during tap change or when an interlock condition exists. An interlock (INTLKB) will be asserted if either temperature readouts exceed an ad-justed setpoint.

The Vernier position signal is supplied to the PC board and displayed as a 0-100% reading on a ten segment LED bar graph. The signal is about 1.0 to 4.0 VDC.

The bus temperature is from a 10 K ohm thermistor. System temperature is a variable voltage from the POD, as discussed elsewhere. Circuitry in the PC board converts these signals to voltages which are displayed on multicolor bar graphs. When the signal exceeds that which lights one red bar, the interlock is tripped.

The output voltage of the test set is supplied at jacks J1 and J2.

Indicator Control Panel

Input Voltage Meter: This LED panel meter indicates the approximate input voltage applied to the test set.

Control Power ON switch: This green switch turns on 120 VAC control power to the test set, and its green lamp lights when ON.

Control Power OFF switch: This red switch turns off the 120 VAC control power



to the test set.

Main Power READY switch: This green switch turns on the main power to the output section of the test set, and its green lamp lights when ON.

Main Power INTERLOCK switch: This red switch turns off the main power to the test set. It lights if an interlock condition is detected.

Output ON indicator: This yellow lamp lights when output voltage is ON.

Output Voltage jacks: These banana jacks are connected to output stabs 1 and 8 in the PI2500, and stabs 1 and 4 in the AUX-5000 and may be used to monitor voltage on the breaker with a DMM.

Thermal Status - Bus: This multicolor bar graph indicates approximate temper-ature of the output bus. Green bars indicate normal temperature. Yellow bars indicate significant heating, and heavy testing should be postponed until unit cools. Red bars indicate overheating, and unit must cool to yellow range before testing. Output initiation will be inhibited if second red bar lights. Excessive temperature may indicate poor output connections.

Thermal Status - System: This indicates temperature of the output section, and other conditions, as determined by the POD. A thermistor in the winding of the first section of the output transformer provides actual temperature, but the POD also calculates a “virtual” temperature based on overload duty cycle limits as indicated in the specifications. The ten bar graph LEDs correspond to tem-peratures of approximately 80 to 280 degrees F, with about 20 degrees per bar. Testing is allowed up to a reading of two red bars but will then be inhibited until temperature cools to no more than four yellow bars.

Coarse Tap Switch: This rocker switch selects the coarse tap. The unit powers up in tap 1. Pressing the switch briefly UP or DOWN will raise or lower the tap by one. Holding it will change taps about one per second.

Coarse Tap Indicator: This seven-segment red LED indicates tap position from 1 to 9.

Vernier Indicator Bar graph: This ten-segment red LED indicates approximate Vernier position. 0 or 1 segment lit indicates minimum position, and 9 or 10 seg-ments lit indicates maximum position.

Vernier Adjust Switch: This rocker switch adjusts the Vernier position. Pressing it briefly UP or DOWN causes the Vernier to move by a very small increment, for fine control. Holding it for about a second will cause the Vernier to move very quickly, for rapid rough adjustment.



Figure II-2 – Indicator Control Panel

ThermalStatus

Bus

Vernier

Up

Down

Up

Down

ON

Stab

Voltage

READY

INTERLOCK

ON

OFF

OutputMainControl

Coarse Tap VernierPower

Input Voltage

0%

50%

100%

Electrical Test Instruments, Inc.

Indicator Control Panel

Power

Input

Selector

Error

Electrical Test Instruments PI-2500 and PI-5000 Section II – Detailed Description ==============================================================================


MEMORY AMMETER CONTROLLER MAC-21

INSTRUCTION MANUAL Firmware Version 3.06 and above

Electrical Test Instruments, LLC 1301 Avondale Road, Suite J

New Windsor, MD 21776 www.ETIPrecision.com

(410) 857-1880

Fax (410) 857-1387

Electrical Test Instruments MAC-21 Section III – MAC-21 ==============================================================================

============================================================================== Copyright(C) 1994-2004 Electrical Test Instruments, LLC All Rights Reserved Page III-1

MAC-21 Specifications INPUT POWER: 120 VAC, SINGLE PHASE 50/60 HZ, 20 VA Max

CURRENT RANGES: 0-1,000 / 5,000 / 25,000 / 100,000 Amperes CURRENT ACCURACY: +/- 0.5% Reading + 0.5% Range + 1 Digit (Continuous) +/- 1.0% Reading + 1.0% Range + 1 Digit (Pulse > 0.01 sec) TIMER RANGES: 0-9.999 / 0-99.99 / 0-999.9 / 0-9999 Seconds 0-999.9 / 0-9999 Cycles TIMER ACCURACY: +/- 0.005 sec +/- 0.005% of reading +/- 1 count DIMENSIONS AND NET WEIGHT Height: 7.0 in. (178 mm) Width: 19.0 in. (483 mm) Depth: 2.0 in. (51 mm) Weight: 3.7 lb. (1.68 kg) STANDARD ACCESSORIES Remote Initiate cable 1 S-B143

Contact Leads 1 pair S-A108



MAJOR PARTS IDENTIFICATION AND OPERATION MAC-21 Control Panel TIME DISPLAY: This 4-digit LED display normally indicates the elapsed time of a cur-rent pulse. In SECONDS mode, it displays time up to 9.999 seconds, then auto ranges to 99.99 seconds, 999.9 seconds, and 9999 seconds. In CYCLES mode, it reads time (based on 60 Hz), up to 999.9 cycles, then auto ranges to 9999 cycles. If time exceeds maximum display capacity (10,000 seconds or 10,000 cycles), the display will read "OVER". In PRESET mode, the display indicates the maximum time of initiation (ON time), in either cycles or seconds. A reading of zero disables the PRESET function and allows any time. CURRENT DISPLAY: This 4-digit LED display indicates the output current. In CONTINUOUS mode, as well as in MEMORY mode before and during a test, the dis-play indicates true-RMS output current in real time. After completion of a test, in MEMORY mode, the display shows the true-RMS value as computed over the entire length of the pulse. This mode is indicated by a flashing LED on the MEMORY key. If a reading exceeds the maximum value for the selected range, the display will read "OVER". This display is also used When the time base is in SECONDS mode, press the STOP key to display the last average RMS value displayed in CONTINUOUS mode. This is useful for pickup tests. It may not be accurate for times less than 1 second. INITIATE key: This key is used to turn ON the output of the test set. The LED in the key indicates that the MAC-21 is attempting to turn the output ON, but other conditions (such as interlocks) could keep the output from actually turning on. In MOMENTARY mode, the key must be held to keep output current on. In MAINTAIN mode, once cur-rent is detected, the output will stay on until the breaker trips, or the STOP or RESET button are pressed. The MAC-21 must be RESET in order to initiate output, and in N.C. or N.O. contact modes, the contact status (continuity) must indicate that the breaker is closed. If the output on time exceeded the PRESET time, as indicated by flashing of the PRESET key LED, the INITIATE key will automatically reset the MAC-21 and turn the output on. STOP key: This key is used to turn the output of the test set OFF. Its LED indicates that output is not being turned on by the MAC-21, but other conditions could cause output voltage to be ON. Use of this key is usually necessary only when in MAINTAIN mode, and it is necessary to abort the test before the breaker trips. NOTE: It is im-portant to realize that the interlock system of the circuit breaker test set may also turn the output off, but it will turn back ON when the interlock condition is cleared (in N.O. and N.C. modes only). RESET key: This key reset the displays on the MAC-21, and arms the pulse reading sys-tem. The LED on the key indicates that the system is reset and armed. RESET also



takes the unit out of PRESET ADJUST mode. MAINTAIN key: This key toggle the MAINTAIN mode for initiation; its LED indicates that this mode is enabled. When in MAINTAIN mode, the INITIATE key need only be pressed briefly to turn output on. MAINTAIN must be set in order to read pulse cur-rent when output is initiated by means other than the MAC-21. For test sets with motorized Vernier, the MAINTAIN key may be pressed while output is ON to provide automatic current hold. The LED in the MAINTAIN key will blink while this mode is set, and the Vernier motor will be activated whenever the current varies more than 5 amperes from the value displayed when the key was pressed. The key may be pressed again to return to normal mode. STOP or RESET will also discontinue current hold. N.O. key: This key is used to set the Normally Open contacts mode. In this mode, lack of continuity on the CONTACTS binding posts indicates that the protective device un-der test is in its normal (non-tripped) mode, and ready to accept current. In N.O. mode, after the INITIATE key is pressed, the timer starts when current (about 3% of range) is detected. The timer stops when the STOP key is pressed, or continuity is sensed at the CONTACTS binding posts. Timing accuracy in this mode is typically +/- 0.01 seconds. N.C. key: This key is used to set the Normally Closed contacts mode. In this mode, continuity on the CONTACTS binding posts indicates that the protective device under test is in its normal (non-tripped) mode, and ready to accept current. This mode may be used for testing multi-pole breakers by connecting the CONTACTS binding posts to an unused pole. In N.C. mode, the timer starts as soon as current (about 3% of range) is detected after the INITIATE key is pressed and stops when the STOP key is pressed or a break in continuity is sensed at the CONTACTS binding posts. Timing ac-curacy in this mode is typically +/- 0.01 seconds. C.L. key combination: When the N.O. and N.C. keys are pressed simultaneously, both LEDs light, indicating C.L. mode (Current Latch). This is the normal power-up default mode for the test set, and is recommended for all tests, unless there is a good reason for using contacts to sense trip. In this mode, current is continuously sampled, and when it exceeds approximately 10% of the current range value, the timer starts, and calculation of pulse current begins. When current stops (or drops below a dynamically determined threshold value), the timer stops running, and the final value for pulse current is calculated and displayed. If the output was initiated by the MAC-21, it is turned OFF. NOTE: in C.L. mode only, the contacts jacks may be used for remote initi-ation (see below). PRESET key: This key toggle the PRESET ADJUST mode, indicated by illumination of its LED. When PRESET ADJUST is active, the adjacent SECONDS and CYCLES keys re-spectively lower and raise the preset time in seconds or cycles, depending on the time base that was selected. Both keys may be pressed simultaneously to reset the time limit to zero, which disables the time limit function. When not in PRESET mode, the LED will flash if the displayed time exceeds the preset limit.



SECONDS key: This key normally selects the SECONDS time base. If the PRESET mode is selected, this key is used to LOWER the preset time limit by decrements of 1.000 second (5.000 seconds above 10.00) with the SECONDS time base, or 1.0 cycles with the CYCLES time base. If it is held, the reading will decrease at a rate of about 5 intervals per second. If a preset time limit was set in SECONDS mode, the output will be turned off within 200 milliseconds of the limit. SECONDS or CYCLES time base may be selected at any time before, during, or after a test. CYCLES key: This key normally selects the CYCLES time base. If the PRESET mode is selected, this key is used to RAISE the preset time limit by increments of 1.000 sec-onds (5.000 seconds above 10.00) with the SECONDS time base, or 1.0 cycles with the CYCLES time base. If it is held, the reading will increase at a rate of about 5 intervals per second. If a preset time limit was set in CYCLES mode, the output will be turned off within several milliseconds after the limit has been reached. SECONDS or CYCLES time base may be selected at any time before, during, or after a test. MEMORY key: This key toggle the MEMORY mode, indicated by illumination of its LED. When in CONTINUOUS mode (LED off), the current display always reads the real-time continuous output current of the test set. In MEMORY mode (LED on), the cur-rent display will read the continuous output current until the test is complete. At this time, the LED will flash, and the display will read the computed true-RMS value of the entire current pulse for the duration indicated on the TIME display. This key may be pressed at any time before, during, or after the test, to toggle between the two modes. As described above, pressing the STOP key provides access to display of peak RMS and last average RMS current. 1000 A range key: This key selects the 1000 ampere range, which provides best accu-racy of readings up to about 1000 amperes. Nominal currents close to this limit, when applied to the device under test, will sometimes cause higher peak currents, causing the display to read "OVER", indicating an overrange condition. If this happens, select the next higher range. Pressing any range switch will also RESET the MAC-21. 5 KA range key: This key selects the 5.000 KA range, for output currents up to about 5,000 amperes. See above for information common to all ranges. 25 KA range key: This key selects the 25.00 KA range, for output currents up to about 25,000 amperes. See above for information common to all ranges. 100 KA range key: This key selects the 100.0 KA range, for output currents up to about 100,000 amperes. See above for information common to all ranges. CONTINUITY lamp: This LED lights when continuity is detected at the CONTACTS binding posts in N.O. and N.C. modes. The beeper will also sound whenever contacts change state. CONTACTS/REMOTE jacks: These jacks provide a low-power AC signal which detects continuity in N.O. and N.C. modes, or is used with a pushbutton cord switch for



remote initiate function (see below). A resistance of about 200 ohms or less will be in-terpreted as continuity. Although the signal is low power and transformer isolated, it is good practice to avoid touching any conductive surface connected to these termi-nals. CAUTION: NEVER CONNECT THESE TERMINALS TO ANY LIVE CIRCUIT! REMOTE INITIATE: In C.L. mode only, the CONTACTS jacks provide a remote initiate function. For safety reasons, this function is disabled in MAINTAIN mode, unless a pre-set value is set in CYCLES time base. SERIAL port: This standard serial port may be connected to a printer, computer, or other device to print or store time and current values of test results in ASCII format. It is set for 9600 baud, 8 bits, 1 stop bit, no parity, no flow control. This information is sent at the end of each test, or by pressing the Stop and Reset keys. Report Generator Software Option: we also offer a software package for a Windows based computer that takes the data from the serial port and inserts time and current values into an excel document. Must have Microsoft office installed for this software to function properly. This can be custom tailored to Your excel document or use the ge-neric document that is provided with the software



MAC-21 Internal Parts INPUT CONNECTOR: This connector, located on the upper rear corner of the MAC-21, provides 120 VAC control power, and connects to the air core CT (current sensor), and initiate circuitry of the test set. The wiring of this connector is essentially compatible with that of the EIL Accu-Amp and is designed to facilitate removal of the MAC-21 for service or shipment. Additional pins are used to provide isolated logic level control for motorized Vernier raise and lower for the current hold feature. Figure II-2: MAC-21 Front Panel



SERVICE INFORMATION AND DOCUMENTATION MAINTENANCE AND CALIBRATION OF THE MAC-21 The MAC-21 is manufactured using solid state components that should not re-quire extensive maintenance. However, the accuracy of the MAC-21 is critical to the testing of circuit breakers and is dependent upon the output of an air-core current sensing coil, which could change due to movement caused by shock or vibration encountered in transporting the test set. Other factors which may affect calibration are contact resistance in the control cable, unusual magnetic fields, insulation leakage, and aging of electronic components in the MAC-21. Therefore, proper operation and calibration should be checked at regular in-tervals and adjusted if proper equipment is available. The inherently delicate nature of electronic circuitry and metering make it generally inadvisable to leave the MAC-21 fastened into the breaker test set while it is being transported, and subject to shock and vibration. The standard rack-mount hardware and twist-lock connector make it simple to remove the MAC-21 and carry it separately.

Field calibration of the MAC-21 may be performed as follows: 1. Obtain a current measuring calibration standard capable of reading TRUE-

RMS current up to at least 1000 Amperes to an accuracy of at least 0.25%. This may consist of a shunt or current transformer, in conjunction with a digital multimeter or laboratory grade AC ammeter.

2. Set up the breaker test set for normal breaker testing. If adjustments are anticipated, remove the MAC-21 from the test set.

3. Connect the calibration standard to the desired output tap. If cables are used, it is recommended that they be twisted so as to minimize radiation and pickup of stray magnetic fields.

4. Apply power to test set and allow at least one minute for circuits to stabi-lize.

5. Check ammeter zero in all ranges. If reading on current meter is greater than 1% of range, internal zero adjustment may be required.

6. Set MAC-21 Range to 1000 A and adjust output of breaker test set to exactly 800 Amperes. If Coarse Tap is 1, and Output Control Vernier is less than 50%, additional resistance must be added to output circuit. This is



important, because waveform distortion is more prevalent at lower levels.

7. If the MAC-21 reading differs from the standard by more than rated accu-racy, adjust the gain potentiometer on the analog board for proper read-ing. If an error of more than 5% is noted, and unit has been in service, the accuracy and validity of previous tests may be questionable; otherwise, there may be a problem in the test setup.

8. Check calibration at 200, 400, 600, and 1000 Amperes.

9. Adjust the current to zero, and press RESET key.

10. Raise the current slowly, until the timer begins to run. This is the Current Latch Threshold, which should be about 10% of range.

11. Set the current at 50% of full scale (500 A) and stop the current.

12. Set the MAC-21 to MEMORY mode and press the RESET Switch.

13. Initiate a fast-momentary pulse of no more than 6 cycles (0.1 Sec) duration. The meter should read the same value, within 1% of reading + 1% of range, that was set in step 11 above.

14. Check pulse reading operation in this manner for currents of 200, 400, 600, and 1000 Amperes, and varying duration.

15. Set Timer Time base to SECONDS. Press Master Reset Switch. Set N.O. mode. Using a stopwatch, initiate for exactly ninety (90) seconds. Timer should read 90.00 Seconds, +/- 0.01 Seconds. (Note: actual reading may vary because of inability to control and measure pulse length.)

16. If everything checks out, the MAC-21 can be assumed to be in calibration, and no other adjustments are required.



PARTS LIST (MAC-21): The overall schematic is on the following pages. The parts list is provided below. Please refer to both when ordering replacement parts.

ITEM QTY DESCRIPTION Part Number

1 1 MAC-21 Contact/LED Harness S-B369 2 1 MAC-21 Rear Panel Harness S-B368 3 1 MAC-21 Metal Cage M-D464 4 1 MAC-21 Main PCB M-C492 5 1 MAC-21 Membrane Switch Panel M-D462 6 6 LOCKWASHER, INT TOOTH #4 M-A116 7 6 SCREW, PH, 4-40x1/4 M-A118 8 2 HANDLES, BRASS, NICKEL PLT, 4" M-C103 9 4 SCREW, RH, 10-32x1/2 M-A158 10 4 FLATWASHER, #10 M-A159 11 4 LOCKWASHER #10 M-A160 12 4 SCREW, PH, 10-32X3/4 M-A191 13 4 NYLON WASHERS #10 M-A155 14 2 JACKSCREW, .312, W/HARDWARE M-A125 15 4 SCREW, PH, 6-32x1/4 M-A139 16 1 COMMUNICATION CABLE S-A106

Electrical Test Instruments MAC-21 Retrofit Package Section III – MAC-21 ===============================================================================================================

============================================================================================================= Copyright(C) 1994-2003 Electrical Test Instruments, LLC All Rights Reserved

Connections (MAC-21):

Electrical Test Instruments MAC-20 Retrofit Package Section III – MAC-20

===============================================================================================================

============================================================================================================= Copyright(C) 1994-2008 Electrical Test Instruments, LLC. All Rights Reserved

Electrical Test Instruments PI-2500 and PI-5000 Section IV - Operating Instructions ==============================================================================


SECTION IV

OPERATING INSTRUCTIONS

Electrical Test Instruments PI-2500 and PI5000 Section IV - Operating Instructions ==============================================================================

============================================================================== Copyright(C) 1994-2008 Electrical Test Instruments, LLC. All Rights Reserved Page IV-1

SECTION IV

OPERATING INSTRUCTIONS PRE-TEST INSTALLATION AND SET-UP (PI2500) 1. The following components of the test set should be available and in good

condition:

a) PI-2500 Main Unit

b) Series bars (three pieces)

c) Stab adapter plate assemblies (one set of four)

d) Allen wrench (hex) to match socket head bolts

e) Pneumatic or electric power ratchet

f) Stab set or cables to match breaker to be tested

g) Input power plugs and cables

h) Input ground lead

i) Auxiliary ground lead

j) Contact lead set (If applicable)

k) Remote initiate cable (optional)

2. For 1000-amp output mode

a) Attach series bars from output terminals 2 to 3, 4 to 5, and 6 to 7.

b) Make sure they fit snugly between the output bus bars, and tighten the bolts

c) Attach cables as needed between output terminals 1 and 8.

d) Make sure selector switch is set to 1000

3. For 2000-amp output mode

a) Attach series bars from output terminals 2 to 3, and 6 to 7.

b) Make sure they fit snugly between the output bus bars, and tighten the bolts

c) Place the stab plate adaptor assembly stamped #1 on output bus #1, making sure it aligns into the slot on the stab adaptor support block

d) Tighten bolts securely.

e) Repeat for stab plate adaptor assemblies stamped #4, #5, and #8



f) When all parts are properly assembled, the bolt pattern should match standard stabs

g) Make sure selector switch is set to 2000

4. Alternate 1000-amp output mode

a) Connect series bars and stab adaptor assemblies per instructions for 2000-amp mode above.

b) Connect a cable or bus bar between stab plates stamped #4 and #5.

c) Connect cables for breaker testing to stab plates stamped #1 and #8

PRE-TEST INSTALLATION AND SET-UP (PI5000) 1. The following components of the test set should be available and in good

condition:

a) PI-2500 Main Unit

b) AUX-5000 Auxiliary Unit

c) Allen wrench (hex) to match socket head bolts

d) Pneumatic or electric power ratchet

e) Stab set or cables to match breaker to be tested

f) Series bar (optional)

g) Input power plugs and cables

h) Input ground lead

i) Auxiliary ground lead

j) Contact lead set (If applicable)

k) Remote initiate cable (optional)

2. Remove any bus work or cables from the output bus terminals of the PI2500

3. Make sure surfaces (especially on top) are clean and smooth.

4. Loosen bolts and nut plates on AUX-5000 so that about ½” gap is between bus input connections and nut plates.

5. Make sure underside of AUX5000 input bus connections are clean and smooth.

6. Position the PI2500 in optimal place for testing, and lock casters.

7. Align the AUX5000 in-line with the PI-2500, and carefully roll it directly to-ward the output bus connectors.



8. When the bus connectors are nearly touching, verify that the bus bars of the AUX5000 fit just over the bus bars of the PI2500. It may be necessary to adjust the two units slightly while pushing together. You may apply a little weight to the PI-2500 to achieve correct alignment. Do not ram the units together, as this may damage the bus connections.

9. When the two sections are as close together as possible (without hitting the stab, adaptor supports on the PI2500), tighten all the bolts. Be sure to turn each one a little at a time until they are snug, before torqueing them tight, to avoid jamming and galling the threads.

GENERAL TEST PROCEDURES (for both PI2500 and PI5000)

1. Additional requirements for testing are as follows:

a) Breakers to be tested

b) Manufacturers' curve data

c) Test log and/or report forms (See examples at end of section)

d) Basic hand tools (wrench, screwdriver, etc.)

e) Safety equipment (safety glasses, gloves, etc.)

f) Reliable and sufficient power source

g) Clean, spacious, and well-lit work area.

2. The voltage selector must be set to match input voltage.

3. Calculate KVA requirements for the source per manufacturer’s manual.

4. Locate a suitable earth ground and connect it to the Unit with at least #6 AWG wire.

5. Connect the Ground Integrity binding post separately to earth ground.

6. If possible, TURN OFF power at source.

7. Connect power source to input, using connectors supplied.

8. Turn on power at source, if turned off in step 6 above.

9. Input Voltage meter should indicate actual line voltage. Verify that voltage selector is set for this voltage. Input selector error LED should light if incor-rect.

10. Verify that Ground Open LED is not lit. Control power cannot be turned on if ground integrity is not sensed.

11. Press Control Power switch. Green lamp should light, control panel should power up to tap 1, and MAC-20 should power up. Fans should run.

12. If Interlock lamp is not lit, press Main Power Ready switch. Main



contactor(s) should energize, and green lamp should light.

13. Connect breaker under test to appropriate output tap, using stabs or ca-bles and series bar as required.

14. Make sure that breaker is CLOSED.

15. Follow Step-by-Step procedures below, as required, for testing.

16. When tests are completed, press INTERLOCK switch to turn Main Power OFF.

17. Press Control Power Off switch to turn Control Power OFF.

18. Turn off supply power, if possible, and disconnect input power cables.

19. Remove ground cables from Main Control Unit to earth ground.



BASIC GUIDELINES AND SUGGESTIONS 1. Best timing and current accuracy will be obtained with the MAC-20 in cur-

rent latch (C.L.) mode.

2. Current Latch modes are preferred for most testing purposes. Exceptions are:

a) Non-series-connected devices such as motor overload relays or shunt-trip breakers.

b) Ratioing of current transformers.

c) Heat runs of cables, bus work, etc. (Connect contacts to thermostat).

3. If Contacts Mode is selected, use caution when connecting continuity sens-ing cables. Although the voltage and current are minimal, under some con-ditions it could cause electrical shock. ALWAYS connect one clip at a time, and NEVER rest the other hand on any current-carrying parts of the breaker while the test set is powered up.

4. Always choose an ammeter range that allows the test current to be read in the area from 20% to 80% of the maximum. This provides greatest accuracy of readings, least chance of overrange, and optimum current latch opera-tion.

5. To obtain maximum output current from the test set, especially when us-ing output cables, it is important to minimize both input and output im-pedance. This can be accomplished by using the largest cable size possible, or using multiple cables in parallel, to reduce resistance, and by keeping ca-bles close together by tying or twisting, to reduce inductance.

6. For all breaker test sets, much better output current waveform and stability can be achieved when the controls of the test set are in their higher posi-tions. To test smaller breakers, it is helpful to introduce additional output impedance, by using some length of adequate, but lighter gauge, wire to connect the breaker to the output connections. When using tap 1, the Ver-nier control should always be at least at 30% to produce desired test cur-rent.



SINGLE POLE MOLDED CASE CIRCUIT BREAKERS Timing Test 1. Consult breaker manufacturer's literature to determine any necessary pre-

cautions and expected test results. A test current of three times the rating of the breaker should be used for this test.

2. Follow steps 1 through 16 in pre-test installation and setup, as required, to set up the breaker test set.

3. Setup MAC-20 for C.L. Maint (MAINTAIN on).

4. Set MAC-20 RANGE to lowest range that is greater than desired test cur-rent.

5. Set TIMEBASE to CYCLES.

6. Press PRESET key. Adjust preset time to 5.0 cycles. This value may be set higher or lower, depending on trip characteristics of breaker.

7. Press PRESET again to return to normal mode.

8. Select MEMORY mode.

9. Repeatedly jog the INITIATE button, while adjusting the OUTPUT CONTROL higher, until the desired test current is read on the ammeter. If insufficient current is obtained at maximum position of the Vernier, set the OUTPUT TAP control to the next higher tap, return the Vernier to zero, and continue.

10. Press RESET button.

11. Set TIMEBASE to SECONDS.

12. Select MAINTAIN mode.

13. Press and release INITIATE key; OUTPUT ON light should glow, timer should run, and current display should read desired output current.

14. While test is running, observe current reading. If necessary, adjust to cor-rect value by using Vernier control, or press MAINTAIN key for current hold.

15. When breaker trips, the test set output should de-energize, timer should stop, and OUTPUT ON light should turn off.

16. Read and record trip current and trip time. Compare to manufacturer's time/current curve.

17. If test is to be repeated, make sure that breaker cools completely.

18. Shut down test set, disconnect breaker, and prepare for subsequent test-ing or relocation according to steps 18 through 22 in pre-test installation and setup outlined above.



Pick-Up of Instantaneous Element

1. Consult breaker manufacturer's literature to determine any necessary pre-cautions and expected test results. Check the breaker's instantaneous set-ting. Pickup should occur at about that current.








9. Repeatedly jog the INITIATE button, while adjusting the OUTPUT CONTROL higher, until the circuit breaker trips instantaneously. This is the approximate pickup point. If insufficient current is obtained at maximum position of the Vernier, set the OUTPUT TAP control to the next higher tap, return the Vernier to zero, and continue.

10. Close breaker under test.

11. By repeating the test, determine the MINIMUM SETTING of the OUTPUT CONTROL, at which the breaker under test opens immediately, whenever the INITIATE button is depressed.

12. Read and record ammeter reading as instantaneous pick-up of the breaker.




Instantaneous Trip Time Test

1. Perform Instantaneous Pickup Test as outlined above.

2. Adjust controls to obtain current above pickup, at approximate desired multiple of rating.


4. Press the INITIATE button. Breaker should trip instantaneously.

5. Read and record timer and ammeter readings as instantaneous trip time and current.




MULTI-POLE MOLDED CASE CIRCUIT BREAKERS

Timing Test

1. Consult breaker manufacturer's literature to determine any necessary pre-cautions and expected test results. A test current of three times the rating of the breaker should be used for this test.


3. Connect appropriate output tap to one pole of breaker under test.











14. If desired, N.C. mode may be used; connect contacts leads to an unused pole of the breaker.


16. While test is running, observe current reading. If necessary, adjust to cor-rect value by using Vernier control.


18. Read and record trip current and trip time. Compare to manufacturer's time/current curve.

19. Repeat above tests for other poles of the breaker. Allow time for breaker to cool. Note: it is acceptable if all poles of the breaker trip within +/- 15% of the



manufacturer's time range for the value of test current chosen. All poles of the breaker need not trip in exactly the same amount of time.


Pick-Up of Instantaneous Element

1. Consult manufacturer's literature to determine any necessary precautions and expected test results. Check the breaker's instantaneous setting. Pickup should occur at about that current.


3. Setup MAC-20 for C.L. MOM.






9. Repeatedly jog the INITIATE button, while adjusting the OUTPUT CONTROL higher, until the circuit breaker trips instantaneously. This is the approximate pickup point. If insufficient current is obtained at maximum position of the Vernier, set the OUTPUT TAP control to the next higher tap, return the Vernier to zero, and continue.




13. Repeat the above test for the other poles of the circuit breaker.




Instantaneous Trip Time Test

1. Perform Instantaneous Pickup Test as outlined above.









LOW VOLTAGE POWER CIRCUIT BREAKERS Nearly all low voltage power circuit breakers are multi-pole devices. The trip units may be either magnetic with a dash pot or solid-state electronic devices. Test procedures would be the same for either type. However, electronic trip types may incorporate ground fault protection. If so, it is necessary to either block or by-pass ground fault protection when tests are being conducted on phase fault characteristics. This is because the tests are being conducted on one pole at a time, and the ground fault protection would consider this opera-tion to be a ground fault. Most low voltage power circuit breakers have either Long Time Delay, and Short Time Delay, and/or instantaneous tripping characteristics. In this case, for test purposes, it is recommended that the instantaneous unit be set in its maximum calibration. This is to prevent an instantaneous trip while trying to set the current for the Short Time Delay characteristic. Electrical tests to be conducted on low voltage power circuit breakers include timing test on L.T.D.; timing test on S.T.D.; and instantaneous pick-up. It is rec-ommended that the magnitude of test current for the L.T.D. timing test be 3 times coil rating or transformer tap. For timing test on S.T.D. the test current should be about 1.5 times the S.T.D. setting. In both cases, tripping time should be within the manufacturer's published time range. Pick-up of the instantane-ous unit should be +/- 10% of the setting for the electronic device and +/- 20% of the setting for the magnetic device. Testing the instantaneous trip on very large circuit breakers set at or near max-imum calibration may sometimes exceed the capacity of the test set. In most cases, the instantaneous element has several calibration marks between "LO" and "HI". In such cases, it may be necessary to perform the test at one of the lower calibration marks. Always be sure to record the "AS FOUND" settings and return the adjustments to these settings after testing. To perform testing, ad-just the screw to a lower setting that allows the test set to verify that the unit will pick up. If the instantaneous unit picks up at the proper current at a lower calibration point, it may be assumed that the unit will operate properly at higher calibration points. This has been verified by manufacturers and by means of field tests. Specific test procedures for all electrical tests are outlined on the following pages. Timing Test, Long Time Delay



1. Consult breaker manufacturer's literature to determine any necessary pre-cautions and expected test results. A test current of three times the rating of the breaker should be used for this test.


3. Connect appropriate output tap to one pole of breaker under test.












15. Press and release INITIATE key; CLOSE or OUTPUT ON light should glow, timer should run, and current display should read desired output current.

16. While test is running, observe current reading. If necessary, adjust to cor-rect value by using Vernier control, or press MAINTAIN key for current hold.


18. Read and record trip current and trip time. Compare to manufacturer's time/current curve. If necessary, adjust the trip unit and repeat the test.

19. Repeat the above tests for the other poles of the breaker, allowing time for breaker to cool. Note: Results are acceptable if all poles of the breaker trip within the manufacturer's time range for the value of test current chosen. All poles of the breaker need not trip in exactly the same amount of time.




Timing Test, Short Time Delay Note: The breaker's trip time for short time delay will always be less than 30 cy-cles and may be as low as 4-5 cycles. Therefore, setting test current will require some practice. However, the magnitude of the test current is not critical; for in-stance, if the S.T.D. is set for 1000 amperes, there will be little or no difference in timing if a test current of 1500, 2000 or 2500 amperes is used. Set up of controls is the same as for timing test L.T.D. Consult breaker manu-facturer's literature to determine any necessary precautions and expected test results. 1. Follow steps 1 through 8 under Timing Test Long Time Delay.







8. Breaker should trip within 30 cycles (0.5 seconds). When breaker trips, the test set output should de-energize, timer should stop, OUTPUT ON light should turn off.

9. Read and record trip current and trip time. Compare to manufacturer's time/current curve. If necessary, adjust the trip unit and repeat the test.

10. Repeat the above tests for the other poles of the breaker, allowing time for breaker to cool. Note: Results are acceptable if all poles of the breaker trip within the manufacturer's time range for the value of test current chosen. All poles of the breaker need not trip in exactly the same amount of time.

11. Shut down test set, disconnect breaker, and prepare for subsequent



testing or relocation according to steps 18 through 22 in pre-test installa-tion and setup outlined above.

Pick-Up of the Instantaneous Unit 1. Consult breaker manufacturer's literature to determine any necessary pre-

cautions and expected test results. Note: If the instantaneous setting is such that the expected test result is above that which may be easily pro-duced by the test set, a valid test may be performed by adjusting the set-ting to its minimum value. At the end of the test, restore the instantaneous setting to its specified value.








9. Repeatedly jog the INITIATE button, while adjusting the OUTPUT CONTROL higher, until circuit breaker trips instantaneously. This is the ap-proximate pickup point. If insufficient current is obtained at maximum po-sition of the Vernier, set OUTPUT TAP control to next higher tap, return the Vernier to zero, and continue.





14. If trip settings were modified for test purposes, restore them to their origi-nal values.




Instantaneous Trip Time Test 1. Perform Instantaneous Pickup Test as outlined above.









MOTOR OVERLOAD RELAYS The motor overload relay is designed to provide overload protection for a mo-tor; therefore, it offers only one time/current characteristic, which is essentially a long-time delay. It may be multi-pole; however, most relays are single pole. In the case of a multi-pole device each pole is tested individually as in the case of a multi-pole direct acting circuit breaker. The motor overload relay contains two separate circuits. The current carrying circuit which contains the relay's operating coil or heater. The control circuit which contains a set of contacts; these contacts open when the relay "oper-ates". It is the opening of these control circuit contacts that deenergizes the motor starter holding coils, thus allowing the starter contactors to open, shut-ting down the motor. Timing Tests 1. Consult the relay manufacturer's literature to determine any necessary

precautions and the expected timing test results. The test current should be 3 to 4 times the rating of the relay operating coil or heater.








9. Connect the relay operating coil or heater circuit terminals to the breaker test set common terminal and the proper output tap terminal.

10. Connect the relay control circuit contacts to the CONTACTS terminals and determine that they are closed by observing the CONTINUITY lamp.





13. Set MAC-20 to N.C. mode. Set MAINTAIN on.

14. Press and release INITIATE button; OUTPUT ON light should glow, timer should operate, and current should indicate on display.

15. When the relay control circuit contacts open, the test set output should deenergize and the timer should stop.

16. Read and record the test value of current and the time of the test. Com-pare the results to the manufacturer's specifications. If possible, adjust the relay. Usually, if the relay time of operation is incorrect, it is necessary to re-place the relay heater with one of the recommended sizes for the motor being protected. If a check test is desired, the relay must be allowed to cool for a period of time (approximately 15 to 30 minutes).

17. For a multi-pole relay, repeat the above tests for the other relay poles.




RATIOING CURRENT TRANSFORMERS To conduct a ratio test on a current transformer, a good multi-range bench ammeter is required in addition to the breaker test set. The breaker test set supplies primary current to the transformer and the bench ammeter is used to read the transformer secondary current. It is suggested that a graph of the test results be plotted. Primary current should be the abscissa and corre-sponding secondary current the ordinate of the graph. WARNING: It is extremely important that the secondary circuit of the current transformer never be broken or opened while the primary circuit is energized. Should the secondary circuit of an energized current transformer be opened, the collapsing magnetic field generates an extremely high voltage across the open ends of the circuit until the resultant arc is extinguished. Under these conditions, personal injury and/or damage to the current transformer under test are probable.


2. Connect the current transformer primary terminals to the breaker test set common terminal and the proper output tap terminal.

3. Connect the current transformer secondary terminals to the bench amme-ter.

4. Set the MAC-20 to N.O. mode. Set MAINTAIN on.

5. Press and release INITIATE button; CLOSE or OUTPUT ON light should glow, timer should operate, and current should indicate on display.

6. Adjust OUTPUT CONTROL higher until the desired current transformer pri-mary current is read on the MAC-20 ammeter. Adjust OUTPUT TAP switch, if necessary, to obtain required current.

7. Read and record the readings on both the breaker test set (MAC-20) and the bench ammeter.

8. Repeat steps 6 and 7 until the desired number of test points have been ob-tained. Note: It is suggested that test points be obtained in multiples of the current transformer rating. For instance, for a 200/5 current transformer, test points would be obtained at primary currents of 200, 400, 600, 800 amperes, etc.

9. Shut down test set, disconnect CT, and prepare for subsequent testing or relocation according to steps 18 through 22 in pre-test installation and setup outlined above.

Electrical Test Instruments PI-2500 and PI-5000 Section V - Service Information and Documentation

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===================================================================================== Copyright(C) 1994-2008 Electrical Test Instruments, LLC. All Rights Reserved

SECTION V

SERVICE INFORMATION AND DOCUMENTATION



SECTION V

SERVICE INFORMATION AND DOCUMENTATION MAINTENANCE AND CALIBRATION OF THE PI-2500 and PI-5000 The PI-2500 and PI-5000 require only minimal maintenance. Mechanical components such as casters and hinges may need periodic lubrication. External surfaces should be kept clean, and screws on access panels should be checked for tightness. The output stab adapter plates and interconnecting bus connections must be kept clean and smooth, and studs should be maintained in good condition. Poor output connections are the main cause of overheating and poor performance. Occasionally, or more often if used in dusty environments, it is important to inspect and clean interior components. Disconnect from all sources of power and remove all access covers. Carefully blow out any dust and inspect all connections for tightness and any sign of deterioration due to corrosion or overheating. The fans should be cleaned with a damp rag and checked for signs of bearing wear by spinning. Vernier brushes should be inspected for signs of wear or overheating and cleaned or replaced as required. Calibration of the PI-2500 and PI-5000 requires accurate current measurement in 1000A, 2000A, and 4000A connections. Adjustment may be accomplished by means of the potentiometers accessible through the PI-2500 output face plate.

Special Calibration Instructions

The pots on the configuration switch PCB are used to adjust the calibration for 1000A, 2000A, and 4000A modes. They should be set so that the readings are one half or one fourth the readings in full parallel configuration.

There is a difference in calibration between the PI-2500 and the AUX-5000. Two pots are provided on the PI2500 control PCB to adjust for this difference. The pot marked AUX should be used when the AUX5000 is connected, and the pot marked MAIN is used for just the PI-2500.

The MAC-20 should be calibrated for its standard input value.



PARTS LIST (PI-2500):

The overall schematic is on the following pages. The parts list is provided below. Please refer to both when ordering replacement parts.

ITEM QTY DESCRIPTION REF DES ETI Number 1 2 Contactor, 3PST, 90A K1-K2 M-C378 2 2 Contactor, 3PST, 40A K3-K4 M-C377 3 1 Contactor, 4PST, 40A K5 M-C374 4 1 Transformer, paralleling T3 M-C278 5 2 Transformer, CT, 50:5 T4,T5 M-C231 6 1 Timing belt, 21” M-C227 7 1 CT Assembly S-B165

PARTS LIST (AUX-5000):


ITEM QTY DESCRIPTION REF DES ETI Number 1 2 Contactor, 3PST, 90A K1-K2 M-C378 2 6 Contactor, 3PST, 30A K3-K8 M-C377 3 4 Bolt Support M-D202R1

PARTS LIST (Indicator Control Panel):


ITEM QTY DESCRIPTION REF DES Part Number 1 1 Power Supply PS1 M-E101 2 1 Digital Panel Meter M1 M-C163 3 1 Relay, DPDT, 120VAC K1 M-C147 4 3 Relay, DPDT, 12 VDC K2-4 M-C149 5 4 Switch, pushbutton, lighted S1-S4 M-C110 6 1 Indicator DS4 M-C111 7 2 Lens, Red XS2, XDS2 M-C112 8 2 Lens, Green XS1, XS3 M-C113 9 1 Lens, Yellow XDS4 M-C114 10 1 LED, red DS5 M-B251 11 1 Receptacle, 37 pin, male J1 M-C140 12 37 Pin, male, #24-20 XJ1 M-A127 13 1 Control panel PCB Ass’y PCB1 S-B169 14 1 Relay PCB Ass’y PCB2 S-B124 15 1 Metering PCB Ass’y PCB3 S-B122 16 1 Interconnect cable, 10 pos P1 S-A107 17 2 Binding post, black BP1,2 M-B174 18 1 Terminal strip, 8 pos TS1 M-B259 19 2 Handle, brass, nickel plated, 3” M-C174



OVERALL SCHEMATIC (PI-2500)

Electrical Test Instruments PI-2500 and PI-5000 Section VI - Service Information and Documentation

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Electrical Test Instruments Retrofit Package Section V - Service Information and Documentation

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WARRANTY Electrical Test Instruments, LLC, will correct any defect in workmanship or material for two years after date of purchase of any Electrical Test Instruments product. Such corrective measures will be limited to repairing or replacing the unit, at Electrical Test Instruments' option. This limited warranty shall not apply to equipment which has been subjected to negligence, accident or damage by operation, maintenance or storage, or to non-normal use or service. This limited warranty does not cover reimbursements for transportation, removal, installation, repair or replacement, except as may otherwise be specifically agreed to in writing by Electrical Test Instruments. The foregoing is in lieu of all other warranties expressed or implied, and all other obligations or liabilities whether arising under contract, negligence or otherwise, on the part of Electrical Test Instruments. In no event shall Electrical Test Instruments be liable for consequential or special damages, including but not limited to loss of use, loss of income, loss of profit or cost of replacement.

PRIMARY INJECTION CIRCUIT BREAKER TEST SET · 2020-01-07 · PRIMARY INJECTION CIRCUIT BREAKER TEST...

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Transcript of PRIMARY INJECTION CIRCUIT BREAKER TEST SET · 2020-01-07 · PRIMARY INJECTION CIRCUIT BREAKER TEST...